JP2011078903A - Structure for preventing flotation of chain in sludge scraper - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure for preventing the flotation of the chain in a sludge scraper capable of preventing the flotation of the chain in the meshing part with a sprocket by a simple structure. <P>SOLUTION: The sludge scraper for moving the flight plates 3 attached to the chain 2 so as to circulate them to scrape up the sludge of a sedimentation basin is equipped with the guide pins 11 composed of the extension parts of the connection pins of the chain 2 and provided so as to protrude from the side of the chain 2 and guide members 13 for guiding the guide pins 11 from the outside in the diametric direction of a follower sprocket 4B in the meshing part of the chain 2 and the follower sprocket 4B. Each of the guide members 13 has the support plate part 13A supported by the brackets 21 for the guide members and formed along the side of the follower sprocket 4B and the guide plate part 13B formed so as to rise from the support plate part 13A toward the chain 2. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a sludge scraper installed in a sedimentation basin such as a sewage treatment facility or a water purification treatment facility.

  As a conventional example of a sludge scraper installed in a settling pond, there is a type in which a chain is hung around a plurality of sprockets and the settling sludge in the settling pond is scraped by a flight plate attached to the chain (for example, patent document) 1).

  From the viewpoint of rust prevention, most of the constituent members of the sludge scraper provided in water are made of resin, and the chain is also made of resin. However, there is a problem that the resin chain tends to be lifted at the meshing portion with the sprocket as compared with the metal chain. As a method for preventing the chain from lifting up, for example, a structure in which a guide member is disposed around the chain is conceivable. Although not related to the meshing part with the sprocket, in Patent Document 2, a lug piece is provided on the front tooth plate or the rear tooth plate of the chain for the purpose of preventing the chain from lifting in the transport path. A technique for arranging a side rail between the two is described.

Japanese Utility Model Publication No. 6-7804 (FIG. 3) Japanese Patent No. 4010755 (paragraphs [0046], [0047], FIG. 9)

  However, since the flight plate is attached to the outer peripheral side of the chain in the sludge scraper, it is difficult to arrange the chain guide member so as not to interfere with the flight plate at the meshing portion with the sprocket.

  The present invention has been created to solve such problems, and provides a structure for preventing the chain from lifting in a sludge scraper that can prevent the chain from being lifted at a meshing part with a sprocket with a simple structure. It is an object.

  In order to solve the above-mentioned problems, the present invention is a sludge scraping machine that circulates and moves flight plates attached to a chain and scrapes the sediment sludge in a sedimentation basin. A guide pin projecting from a side surface, and a guide member for guiding the guide pin from the outside in the radial direction of the sprocket at a meshing portion between the chain and the sprocket. A structure to prevent lifting.

  According to this structure for preventing the chain from rising, since the guide pin protrudes from the side surface of the chain, the guide member for guiding the guide pin from the radially outer side of the sprocket (that is, the outer peripheral side of the sprocket) is located on the side surface of the chain. Therefore, interference with the flight plate attached to the outer peripheral side of the chain is easily avoided. By making the guide pin an extension of the connecting pin of the chain, the present invention can be easily applied to an existing general-purpose chain.

  Further, according to the present invention, the guide member is supported by a fixed member and formed along a side surface of the sprocket. The guide member is formed to rise from the support plate portion toward the chain. And a guide plate portion having an arc shape along the track.

  According to this configuration, the shape of the guide member becomes simple, and the manufacturing cost of the guide member can be reduced and the assemblability can be improved.

  ADVANTAGE OF THE INVENTION According to this invention, in the sludge scraper installed in a sedimentation basin, the lift of the chain in a meshing part with a sprocket can be prevented with a simple structure. Moreover, by projecting the guide pin from the side of the chain, the flight plate can be attached to the end of the chain, and the flight plate can be extended to the outside of the sprocket (at the bottom of the sedimentation basin). .

It is a sectional side view of the sedimentation basin in which the sludge scraper was installed. It is a partial top view of the chain to which this invention is applied. It is explanatory drawing around the guide member in 1st Example of this invention, (a), (b) is a front view and a side view, respectively. It is explanatory drawing around the guide member in 2nd Example of this invention, (a), (b) is a front view and a side view, respectively. It is explanatory drawing around the guide member in 3rd Example of this invention, (a), (b) is a front view and a side view, respectively.

  In FIG. 1, the sedimentation basin P is attached to an endless chain 2 and circulates in the longitudinal direction of the sedimentation basin P, and the sludge scraper provided with a flight plate 3 that scoops the sludge deposited on the bottom of the sedimentation basin P. A sorter 1 is installed. A pair of chains 2 are arranged side by side in the width direction of the sedimentation basin P (backward-frontward in FIG. 1), and sprockets (driving sprocket 4A, driven sprocket 4B to 4B) installed at a plurality of locations in the sedimentation basin P, respectively. 4D).

  The flight plate 3 is a plate-like member extending in the width direction of the sedimentation basin P, and a plurality of the flight plates 3 are attached to the outer peripheral side of the chain 2 over a pair of chains 2 at predetermined intervals. As shown, it is connected to the chain 2 via an attachment 5. As the drive sprocket 4A is driven to rotate by the drive motor 6 and the chain 2 circulates, the flight plate 3 located in the lower path of the chain 2 scrapes the sludge that has settled on the bottom of the pond, and one end in the longitudinal direction of the settling basin P The sludge is accumulated in the pit 7 formed in the above. The flight plate 3 is guided by guide rails 8 and 9 installed on the side wall of the sedimentation basin P in the upper path of the chain 2, and installed at the bottom of the sedimentation basin P in the lower path of the chain 2. Guide rail 10 is guided.

  In the present invention, as shown in FIG. 2, in the chain 2, the connecting pin 2 </ b> A is extended so as to project from the side surface (outer link plate) to form the guide pin 11, as shown in FIGS. 1, 3 to 5. In addition, the main feature is that guide members 12 to 15 for guiding the guide pin 11 from the outside in the radial direction of the sprockets 4A to 4D are provided at the meshing portions of the chain 2 and the sprockets 4A to 4D.

“First Example”
FIG. 3 shows an application example for the drive sprocket 4A. A bearing bracket 16 is fixed to the housing side surface of the sedimentation basin P, and a drive shaft 18 is rotatably supported on a bearing unit 17 placed on the bearing bracket 16. A drive sprocket 4A is attached to the drive shaft 18 and a drive transmission sprocket 20 connected to the drive motor 6 (FIG. 1) via a chain 19 is attached to the drive shaft 18.

  A guide member bracket 21 (fixing member) extending toward the center of the sedimentation basin P in the width direction is fixed to the bearing bracket 16, and the guide member 12 is fixed to the guide member bracket 21. . The guide member 12 is composed of, for example, a plate member, one end of which is supported by the guide member bracket 21 and formed along the side surface of the drive sprocket 4A, and the other end of the support plate portion 12A from the other end toward the chain 2. And a guide plate portion 12B formed to rise. The guide plate portion 12B is formed in an arc shape so as to follow only the meshing portion between the chain 2 and the drive sprocket 4A, and slightly outside the arc track of the guide pin 11 of the chain 2 on the radially outer side of the drive sprocket 4A. And it is located in the radial direction inside of drive sprocket 4A rather than the circular orbit of flight board 3. In addition, a through hole for inserting the drive shaft 18 is formed in the support plate portion 12A.

  According to the above configuration, the guide pin 11 is prevented from being displaced to the outside of the circular arc track by the guide plate portion 12B of the guide member 12, so that the lifting of the chain 2 with respect to the drive sprocket 4A is suppressed. By adopting a structure in which the guide pin 11 protruding from the side surface of the chain 2 is guided by the guide member 12, interference between the flight plate 3 (specifically, the attachment 5) attached to the outer periphery of the chain 2 and the guide member 12 is avoided. Is also easy. Since the guide pin 11 is an extension of the connecting pin 2A of the chain 2, the present invention can be easily applied to an existing general-purpose chain.

  Further, by forming the guide member 12 from the member having the support plate portion 12A and the guide plate portion 12B, the shape of the guide member 12 becomes simple, and the manufacturing cost and assembly property of the guide member 12 are reduced. Can be improved. The support plate portion 12A and the guide plate portion 12B may be configured by integrally forming different plate members by welding or the like, or may be configured by bending a single plate member.

"Second Example"
FIG. 4 shows an application example for the driven sprocket 4B. A fixed shaft 23 is supported on a shaft support bracket 22 (fixed member) fixed to the side surface of the sediment pond P, and a driven sprocket 4B is rotatably supported by the fixed shaft 23. The guide member 13 has a support plate portion 13A that is supported at one end by the support bracket 22 and formed along the side surface of the driven sprocket 4B, and a guide that is formed to rise from the other end of the support plate portion 13A toward the chain 2. It has a shape having a plate portion 13B. The guide plate portion 13B is formed in an arc shape so as to follow only the meshing portion of the chain 2 and the driven sprocket 4B, and is slightly outside the arc track of the guide pin 11 of the chain 2 on the radially outer side of the driven sprocket 4B. And it is located in the radial direction inner side of driven sprocket 4B rather than the circular arc track of flight board 3. The shaft support bracket 22 is also used in the mounting structure of the guide member 15 for the driven sprocket 4D shown in FIG.

  Also according to the second embodiment, the guide pin 11 is prevented from being displaced to the outside of the circular arc track by the guide plate portion 13B of the guide member 13, so that the lifting of the chain 2 with respect to the driven sprocket 4B is suppressed. Further, by configuring the guide member 13 from a member having the support plate portion 13A and the guide plate portion 13B, the shape of the guide member 13 becomes simple, so that the manufacturing cost of the guide member 13 can be reduced and the assembling property can be reduced. Improvement can be achieved. The support plate portion 13A and the guide plate portion 13B may be configured by integrally forming different plate members by welding or the like, or may be configured by bending a single plate member.

“Third Example”
FIG. 5 shows an application example to the driven sprocket 4C. The driven sprocket 4C is configured such that the shaft can be slid to adjust the tension of the chain 2, and the fixed shaft 25 (fixed member) cannot rotate on the slide shaft support unit 24 fixed to the housing of the sedimentation basin P. It is attached in the longitudinal direction of the sedimentation basin P so that sliding adjustment is possible. The guide member 14 is supported by a fixed collar 26 fixed to the fixed shaft 25 and is formed along the side surface of the driven sprocket 4C. The guide member 14 is formed so as to rise from the support plate 14A toward the chain 2. It has a shape having a plate portion 14B. The guide plate portion 14B is formed in an arc shape so as to follow only the meshing portion between the chain 2 and the driven sprocket 4C, and is slightly outside the arc track of the guide pin 11 of the chain 2 on the radially outer side of the driven sprocket 4C. And it is located in the radial direction inner side of driven sprocket 4C rather than the circular orbit of flight board 3.

  Also according to the third embodiment, the guide pin 11 is prevented from being displaced outward from the circular arc track by the guide plate portion 14B of the guide member 14, so that the lifting of the chain 2 with respect to the driven sprocket 4C is suppressed. Further, by configuring the guide member 14 from a member having the support plate portion 14A and the guide plate portion 14B, the shape of the guide member 14 becomes simple, and the manufacturing cost of the guide member 14 is reduced and the assembly property is improved. Improvement can be achieved. The support plate portion 14A and the guide plate portion 14B may be configured by integrally forming different plate members by welding or the like, or may be configured by bending a single plate member.

  The preferred embodiment of the present invention has been described above. In each figure, the guide pin 11 protrudes from one side of the chain 2 (the side facing the housing side of the sedimentation basin P) and is guided by a guide member provided on the outer side of the sprocket. The guide pin 11 may be protruded from the other side of the chain 2 (the side facing the center in the width direction of the sedimentation basin P) and guided by a guide member provided on the inner side of the sprocket. 11 may be projected from both sides of the chain 2 and guided by guide members provided on both sides of the sprocket. In addition, the present invention is not limited to those described in the drawings, and various design changes can be made without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 1 Sludge scraper 2 Chain 2A Connecting pin 3 Flight board 4A Drive sprocket 4B-4D Driven sprocket 11 Guide pin 12-15 Guide member 12A-14A Support plate part 12B-14B Guide plate part 21 Guide member bracket (fixing member)
22 Bracket for shaft support (fixing member)
25 Fixed shaft (fixed member)
P sedimentation pond

Claims (2)

In the sludge scraping machine that circulates the flight board attached to the chain and scrapes the sediment sludge in the sedimentation pond,
A guide pin that is formed by extending the connecting pin of the chain and projecting from the side of the chain;
A guide member that guides the guide pin from the radially outer side of the sprocket at the meshing portion of the chain and the sprocket;
A structure for preventing the chain from lifting in a sludge scraper.   The guide member is supported by a fixed member and has a support plate portion formed along the side surface of the sprocket. The guide member rises from the support plate portion toward the chain, and has an arc shape along an arc track of the guide pin. The structure for preventing lifting of a chain in a sludge scraper according to claim 1, wherein the structure is provided with a guide plate portion.

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